The photoluminescence origin of self-activated tungstates and molybdates

Bangfu Ding; Chao Han; Junying Zhang; Wei Chen; Lun Ma; Zilong Tang

doi:10.1166/sam.2017.2353

The photoluminescence origin of self-activated tungstates and molybdates

Bangfu Ding, Chao Han, Junying Zhang^*, Wei Chen, Lun Ma, Zilong Tang

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

2 Citations (Scopus)

Abstract

Tungstates and molybdates have received extensive attention because of their particular luminescent properties and wide applications. In this paper, we briefly introduce self-activated photoluminescence materials, and then focus on the luminescence origins of tungstates and molybdates. Their luminescence is mainly originated from charge transfer transition, defect recombination, and exciton emission. In addition to matrix luminescence, energy transfer among host, activator, and sensitizer is essential to obtain multicolor emission and higher luminous intensity. Understanding the nature of luminescence can guide the search for a novel self-activated luminescence host and help achieve effective doping for the purpose of gaining high-efficiency luminescence.

Original language	English
Pages (from-to)	306-315
Number of pages	10
Journal	Science of Advanced Materials
Volume	9
Issue number	3-4
DOIs	https://doi.org/10.1166/sam.2017.2353
Publication status	Published - 2017
Externally published	Yes

Keywords

Charge transfer transition
Energy transfer
Exciton
Point defects
Self-Activated photoluminescence

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10.1166/sam.2017.2353

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title = "The photoluminescence origin of self-activated tungstates and molybdates",

abstract = "Tungstates and molybdates have received extensive attention because of their particular luminescent properties and wide applications. In this paper, we briefly introduce self-activated photoluminescence materials, and then focus on the luminescence origins of tungstates and molybdates. Their luminescence is mainly originated from charge transfer transition, defect recombination, and exciton emission. In addition to matrix luminescence, energy transfer among host, activator, and sensitizer is essential to obtain multicolor emission and higher luminous intensity. Understanding the nature of luminescence can guide the search for a novel self-activated luminescence host and help achieve effective doping for the purpose of gaining high-efficiency luminescence.",

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T1 - The photoluminescence origin of self-activated tungstates and molybdates

AU - Ding, Bangfu

AU - Han, Chao

AU - Zhang, Junying

AU - Chen, Wei

AU - Ma, Lun

AU - Tang, Zilong

PY - 2017

Y1 - 2017

N2 - Tungstates and molybdates have received extensive attention because of their particular luminescent properties and wide applications. In this paper, we briefly introduce self-activated photoluminescence materials, and then focus on the luminescence origins of tungstates and molybdates. Their luminescence is mainly originated from charge transfer transition, defect recombination, and exciton emission. In addition to matrix luminescence, energy transfer among host, activator, and sensitizer is essential to obtain multicolor emission and higher luminous intensity. Understanding the nature of luminescence can guide the search for a novel self-activated luminescence host and help achieve effective doping for the purpose of gaining high-efficiency luminescence.

AB - Tungstates and molybdates have received extensive attention because of their particular luminescent properties and wide applications. In this paper, we briefly introduce self-activated photoluminescence materials, and then focus on the luminescence origins of tungstates and molybdates. Their luminescence is mainly originated from charge transfer transition, defect recombination, and exciton emission. In addition to matrix luminescence, energy transfer among host, activator, and sensitizer is essential to obtain multicolor emission and higher luminous intensity. Understanding the nature of luminescence can guide the search for a novel self-activated luminescence host and help achieve effective doping for the purpose of gaining high-efficiency luminescence.

KW - Charge transfer transition

KW - Energy transfer

KW - Exciton

KW - Point defects

KW - Self-Activated photoluminescence

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DO - 10.1166/sam.2017.2353

M3 - Article

AN - SCOPUS:85014229702

SN - 1947-2935

VL - 9

SP - 306

EP - 315

JO - Science of Advanced Materials

JF - Science of Advanced Materials

IS - 3-4

ER -

The photoluminescence origin of self-activated tungstates and molybdates

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Keywords

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